Events in General Relativity

Question

In another forum, I read this question: On page 31 of the book Gravitation there a image in which various events are symbolized by a black dot, absorption of a photon, emission of a photon, collision between particles,etc. What can be said (for example) of the particle -before- it collides with the other particles? The particle is moving freely in the spacetime, but it hasn't yet collided with the other particle, so at moment there is not been any event... How is the state of this particle defined? Someone did this answer: An idea behind the GR, although not always explicit, is that the events constitute a kind of and therefore given an event there will be a neighborhood of events. This allows for use spacetime coordinates as continuous variables.

Could you explain me better?

Answer 1

An event is a point in spacetime, a specific time and place. It is not a physical process. A physical process, like the emission of a photon, happens at some event. But the event itself is the time and place, not the physical process.

Similarly, in geometry a point is a place. You may put a dot at a point, but the dot is not the point and there are an infinite number of other points in a small neighborhood of the point with the dot.

Likewise, a physical process may be used to identify some event, but there is another event at the same place but just a little earlier, and another event at the same time but just a little to the right. The events form a continuum, even if the physical processes are discrete

Answer 2

Writing our book (Kopeikin et al. 2011), we suggested the following definition of event:

Let us consider a physical process taking place within a sufficiently small volume of space and a sufficiently short period of time. One assumes that it is possible to reduce the actual physical process to its limiting content by shrinking the volume and the time interval to zero. This brings to life an idealised notion of event, an often used abstraction of a physical phenomenon taking place at one point in space and at one instant of time. Examples of the events are a photon’s emission or absorption, a collision of two elementary particles, a meteorite’s burst in planetary atmosphere, etc. The event is mathematically identified with a point, and the physical world is considered as consisting of a continuous set of points modeling its underlying mathematical structure. The set of events is further equipped with additional mathematical paraphernalia which convert it into a well explored mathematical object called manifold.

I regret that we did not mention what some call "The Third Postulate of Special Relativity", the principle of invariance of coincidences. Tacitly implied since Einstein's times, this principle was spelled out explicitly by David Mermin in his book "Space and Time in Special Relativity":

When one observer says two events coincide in space and time, so will all other observers.

The principle defines an important aspect of the notion of event. For more on this, see this discussion.

Now, you are asking: "What can be said (for example) of the particle before it collides with the other particles?" In my opinion, this question is answered by the fact that a particle is always interacting with virtual particles. In this sense, an event is happening to the particle at each point of its trajectory.